EP1742375A1 - Correction of adjustment errors between two I and Q paths - Google Patents

Abstract

The method involves determining a current value of an error from a sum of error values between in-phase and quadrature digital signals. The current value is compared with a previous value of the former error. A current phase shift correction value is selected from two phase shift correction values based on the comparison and a previous phase shift correction value. The selected value is added to the previous phase shift to obtain a current phase shift that is introduced between the signals. The current former error and phase shift correction values are stored, and the above steps are repeated. Independent claims are also included for the following: (1) a device for correcting mismatch between in-phase and quadrature digital signals coming from a signal broadcast through a terrestrial path (2) an electronic device for processing phase and quadrature components comprising a mismatch correction device (3) a device for receiving signal broadcast through terrestrial path comprising an electronic device.

Description

The invention relates to the correction of I and Q signal pairing faults from terrestrial broadcast signals.

The invention thus applies in particular to the field of digital terrestrial television, for example as defined in the European DVB-T specification (as "Digital Video Broadcasting-Terrestrial" in English), or in the DVB-H specification ( as "Digital Video Broadcasting-Handheld".

The invention can also be applied to the field of digital broadcasting, as defined for example in the DAB standard (as Digital Audio Broadcasting "in English).

The invention can also be applied to the field of wireless local area networks, as for example defined in the IEEE 802.11 or Hiperlan / 2 standards.

The invention particularly relates to the demodulators and the processing of the broadcast signals received.

In general, in high-speed communications, the transmissions are limited, inter alia, by the distortion of the signal during the propagation. The data can be dispersed over time, creating interference between symbols.

In addition, an over-the-air broadcast signal may be reflected on an obstacle during transmission. The obstacle may for example be a wall, a building or a relief element. The broadcast signal may also be refracted due to the index of a traversed medium, or may be diffracted against an obstacle. Therefore, the signal received by a receiver is the combination of a signal transmitted on a direct path from an emitter and a multitude of attenuated and delayed signals from the different indirect paths.

The transfer function of such a channel is not flat in frequency. In addition, the obstacles, the transmitter or the receiver can be mobile. The transfer function can thus change over time.

It is known to use an OFDM modulation (such as "Orthogonal Frequency Division Multiplexing"). The transmission is ensured by means of a frequency multiplexing of orthogonal subcarriers between them, separated by a guard interval. The modulation step involves an inverse Fourier transform and the demodulation step involves a Fast Fourier Transform (FFT). OFDM modulation makes it possible to transmit signals over a radio frequency channel with relatively high reliability.

In particular, a COFDM modulation (such as "Coded OFDM" in English) can be used. COFDM modulation allows relatively robust transmission to attenuations that may affect the subcarriers.

A radio signal receiving device comprises a tuner. The tuner is used to reposition the received signal in a suitable frequency band. The tuner can thus replace the received signal around an intermediate frequency, or even directly in baseband. In the latter case, the tuner can be realized in CMOS or BiCMOS technology. The tuner can thus have a relatively small size and power consumption, which can in particular be of interest for DVB-H type applications.

The tuner converts the received signal into a phase signal denoted I (as "In phase" in English) and a quadrature signal denoted Q, respectively on a channel I and on a channel Q. The signal I and the signal Q are analog . There may be mismatches between channels I and Q. Pairing faults include phase faults, i.e., the phase shift between the vectors corresponding to signal I and signal Q is not exactly 90 °. The mismatches also include amplitude defects, i.e. the vectors corresponding to the I and Q signals have different lengths.

The patent application FR2853486 discloses a device comprising a baseband tuner, digitizing means, and a digital block. In addition to demodulation means, the digital block includes correction means. These correction means are intended to correct the phase and amplitude matching defects of the I and Q channels. The patent application FR2853486 refers to known algorithms for correcting phase and amplitude matching defects.

For example, an error is measured and a corrective phase shift to be introduced between the signals of the I and Q channels is calculated from this error.

However, these algorithms have proved unsatisfactory in correcting I and Q signal pairing faults from terrestrial broadcast signals.

It is an object of the present invention to provide for correction of I and Q signal pairing faults from over-the-air terrestrial signals that are more satisfactory.

• /a/ mesurer un jeu de valeurs de première erreur pendant une première durée, dont chacune est mesurée à partir d'un symbole estimé provenant du signal radiodiffusé et du symbole théorique le plus proche du symbole estimé,
• /b/ déterminer une valeur courante d'une seconde erreur à partir d'une somme des valeurs de première erreur du jeu de valeurs de première erreur,
• /c/ comparer la valeur courante de la seconde erreur à une valeur antérieure de la seconde erreur conservée en mémoire,
• /d/ choisir la valeur d'une correction de déphasage courante à ajouter à un déphasage antérieur introduit entre le signal numérique en phase et le signal numérique en quadrature, le choix étant effectué parmi au moins deux valeurs de correction de déphasage, à partir du résultat de la comparaison de l'étape /c/ d'une part, et de la valeur d'une correction de déphasage antérieure conservée en mémoire d'autre part,
• /e/ ajouter la valeur de la correction de déphasage courante choisie à l'étape /d/ au déphasage antérieur pour obtenir un déphasage courant,
• /f/ introduire le déphasage courant obtenu à l'étape /e/ entre le signal numérique en phase et le signal numérique en quadrature,
• /g/ conserver en mémoire la valeur courante de la seconde erreur déterminée à l'étape /b/ et la valeur de la correction de déphasage courante choisie à l'étape /d/,
• /h/ répéter les étapes précédentes.

The invention thus provides a method for correcting pairing faults between a digital in-phase signal and a quadrature digital signal from a terrestrial broadcast signal, comprising a phase correction method comprising the steps of at

• / a / measuring a set of first error values during a first duration, each of which is measured from an estimated symbol from the broadcast signal and the theoretical symbol closest to the estimated symbol,
• / b / determining a current value of a second error from a sum of the first error values of the first error value set,
• / c / comparing the current value of the second error with an earlier value of the second error stored in memory,
• / d / selecting the value of a current phase shift correction to be added to an earlier phase shift introduced between the in-phase digital signal and the quadrature digital signal, the choice being made among at least two phase shift correction values, starting from result of the comparison of the step / c / on the one hand, and the value of an earlier phase shift correction stored in memory on the other hand,
• / e / adding the value of the current phase shift correction chosen in step / d / to the previous phase shift to obtain a current phase shift,
• / f / introducing the current phase shift obtained in step / e / between the in-phase digital signal and the quadrature digital signal,
• / g / keeping in memory the current value of the second error determined in step / b / and the value of the current phase shift correction chosen in step / d /,
• / h / repeat the previous steps.

Thus, according to this method, the second error serves as a decision criterion for converging to the correct value of the angle between the I and Q channels. The phase shift to be introduced is not calculated directly from the value of an error. as in the prior art, but apprehended step by step.

The method according to this aspect of the invention is relatively simple to implement and allows correction of mismatches between I and Q channels from relatively efficient terrestrial broadcast signals.

In addition, such a channel is likely to change over time, so that by periodically repeating the process steps, better correction of the phase matching defects can be obtained.

The invention is limited by the order in which the steps / a /, / b /, / c /, / d /, / c /, / e /, / f /, / g / and / h / are presented only when necessary for the operation of the phase correction. For example, the steps / e / and / g / are interchangeable.

Advantageously, the pairing error correction method also comprises a method of amplitude correction.

Advantageously, during step / d /, the choice of the current phase shift correction value is made among strictly two phase shift correction values.

The current value of the second error is compared to the previous value of the second error. The result of the comparison of step / c / can for example include the sign of the difference between the current value of the second error and the previous value of the second error stored in memory. This comparison step makes it possible to estimate whether the second error has increased when the previous phase shift correction has been added, or if on the contrary the second error has decreased.

Advantageously, the strictly two phase shift correction values are of opposite signs to each other.

Thus, in the first case, it can be provided that the value of the current phase shift correction is chosen equal to, or at least the same sign as, the value of the previous phase shift correction. In the second case, it can be provided that the value of the current phase shift correction is chosen at the opposite, or at least opposite, of the value of the previous phase shift correction.

Alternatively, during step / d /, the choice of the current phase shift correction value is made from more than two phase shift correction values. This alternative may in particular be considered for a channel whose transfer function varies relatively little with time. The method thus automatically plays on the speed of convergence.

Advantageously, the phase correction method further comprises a step / i / of waiting for a second duration. This step is performed after the step / e / introduction of the current phase shift and before measuring the first error values used to determine a next value of the second error. This waiting allows a device implementing the method according to this aspect of the invention to regain a steady state following the introduction of the current phase shift. The next value of the second error is thus significant of the effect of the current phase shift.

Alternatively, the phase correction method does not include a waiting step for a second duration. Indeed, it is possible that the device implementing the method according to this aspect of the invention has a relatively low inertia, so that it is not necessary to wait for the second time to obtain significant results.

Advantageously, the first duration is such that the set of first error values comprises at least four first error values.

Indeed, the transfer function of the channel may be likely to vary with time. It may therefore be desirable to measure a number of first error values to obtain a current value of a second significant error.

Alternatively, the first duration is such that the set of first error values comprises less than four first error values.

• des moyens de mémorisation de la valeur d'une correction de déphasage antérieure et de la valeur antérieure d'une seconde erreur,
• un dispositif de mesure de valeurs de première erreur entre un symbole estimé et un symbole théorique le plus proche du symbole estimé,
• des moyens de sommation permettant de déterminer la valeur courante d'une seconde erreur à partir d'une somme des valeurs de première erreur mesurées pendant une première durée,
• des premiers moyens de comparaison pour comparer la valeur courante de la seconde erreur à la valeur antérieure de la seconde erreur conservée en mémoire,
• des moyens de choix de la valeur d'une correction de déphasage courante à ajouter à un déphasage antérieur introduit entre le signal numérique en phase et le signal numérique en quadrature, le choix étant effectué parmi au moins deux valeurs de correction de déphasage, à partir du résultat de la comparaison d'une part, et de la valeur de la correction de déphasage antérieure conservée en mémoire,
• des moyens de déphasage permettant d'introduire un déphasage courant entre le signal numérique en phase et le signal numérique en quadrature, le déphasage courant étant fonction du déphasage antérieur et de la valeur de la correction de déphasage courante.
  Ce dispositif de correction de défauts d'appariement permet de mettre en oeuvre le procédé selon un des aspects de l'invention et présente donc les mêmes avantages.
  De plus, le dispositif de correction de défauts d'appariement de phase selon cet aspect de l'invention peut être intégré dans un dispositif électronique relativement facilement.
  Le dispositif électronique peut par exemple comprendre un démodulateur.
  Avantageusement, des premiers moyens de comptage commandent les moyens de sommation pour autoriser la sommation des valeurs de première erreur pendant la première durée. Cette caractéristique n'est pas limitative.
  Alternativement, les premiers moyens de comptage peuvent commander le dispositif de mesure afin que les mesures de valeurs de première erreur ne soient effectuées que pendant la première durée.
  Avantageusement, des seconds moyens de comptage commandent les moyens de sommation pour autoriser la sommation des valeurs de première erreur seulement après une seconde durée. Ainsi, après avoir introduit un nouveau déphasage, on attend que le dispositif électronique retrouve un régime établi, pour que la valeur courante de la seconde erreur soit significative.
  Alternativement, les seconds moyens de comptage commandent le dispositif de mesure.
  Cette caractéristique n'est pas non plus limitative. En particulier, le dispositif électronique peut avoir une dynamique telle qu'il n'est pas nécessaire d'attendre le temps de la seconde durée pour obtenir un critère de décision significatif.
  Avantageusement et de manière non limitative, des moyens d'estimation de canal sont situés en amont du dispositif de mesure de valeurs de première erreur. De tels moyens d'estimation de canal, par exemple un prédicteur, sont bien connus de l'homme du métier. Les premières erreurs sont ainsi mesurées entre des symboles théoriques et des symboles estimés, l'estimation des symboles comprenant une étape de correction par les moyens d'estimation de canal. En pratique, certains démodulateurs existants comprennent un dispositif de mesure d'erreur en aval d'un prédicteur. Un tel dispositif de correction de phase peut donc être inséré relativement facilement dans des démodulateurs existants.
  Le procédé selon un aspect de la présente l'invention est avantageusement utilisé lorsque le dispositif électronique selon un aspect de l'invention fonctionne en régime établi, mais cette caractéristique n'est pas limitative.
  La présente invention a également pour objet un dispositif électronique de traitement de composantes en phase et en quadrature, respectivement sur une voie en phase et une voie en quadrature, provenant de signaux radiodiffusés par voie de Terre, comprenant
• un dispositif d'estimation de symboles à partir d'un signal numérique en phase et d'un signal numérique en quadrature correspondant respectivement à la composante en phase et à la composante en quadrature, et
• un dispositif de correction de défauts d'appariement selon un aspect de la présente invention.

The present invention also relates to a device for correcting pairing faults between a digital in-phase signal and a quadrature digital signal, respectively on a in-phase channel and a quadrature channel, originating from a radio-broadcast signal. Earth and intended for a symbol estimation device from the in-phase digital signal and the quadrature digital signal, the correction device comprising a phase correction device. The phase correction device comprises:

• means for storing the value of an earlier phase shift correction and the previous value of a second error,
• a first error value measuring device between an estimated symbol and a theoretical symbol closest to the estimated symbol,
• summing means for determining the current value of a second error from a sum of the first error values measured during a first duration,
• first comparison means for comparing the current value of the second error with the previous value of the second error stored in memory,
• means for selecting the value of a current phase shift correction to be added to an earlier phase shift introduced between the in-phase digital signal and the quadrature digital signal, the choice being made among at least two phase shift correction values, starting from the result of the comparison on the one hand, and the value of the previous phase shift correction stored in memory,
• phase shift means for introducing a current phase difference between the in-phase digital signal and the quadrature digital signal, the current phase shift being a function of the previous phase shift and the value of the current phase shift correction.
  This pairing error correction device makes it possible to implement the method according to one of the aspects of the invention and thus has the same advantages.
  In addition, the phase matching defect correction device according to this aspect of the invention can be integrated into an electronic device relatively easily.
  The electronic device may for example comprise a demodulator.
  Advantageously, first counting means control the summing means to allow summation of the first error values during the first duration. This characteristic is not limiting.
  Alternatively, the first counting means can control the measuring device so that the first error value measurements are made only during the first duration.
  Advantageously, second counting means control the summing means to allow summation of the first error values only after a second duration. Thus, after introducing a new phase shift, it is expected that the electronic device regain a steady state, so that the current value of the second error is significant.
  Alternatively, the second counting means control the measuring device.
  This characteristic is not limiting either. In particular, the electronic device may have a dynamic such that it is not necessary to wait for the time of the second duration to obtain a significant decision criterion.
  Advantageously and in a nonlimiting manner, channel estimation means are located upstream of the first error value measuring device. Such channel estimation means, for example a predictor, are well known to those skilled in the art. The first errors are thus measured between theoretical symbols and estimated symbols, the estimation of the symbols comprising a correction step by the channel estimation means. In practice, some existing demodulators include an error measuring device downstream of a predictor. Such a phase correction device can therefore be inserted relatively easily in existing demodulators.
  The method according to one aspect of the present invention is advantageously used when the electronic device according to one aspect of the invention operates in steady state, but this feature is not limiting.
  The present invention also relates to an electronic device for processing in-phase and quadrature components, respectively on an in-phase channel and a quadrature channel, originating from terrestrial broadcast signals, comprising
• a symbol estimation device from a digital in-phase signal and a quadrature digital signal corresponding respectively to the in-phase component and the quadrature component, and
• a pairing error correction device according to one aspect of the present invention.

• un syntonisateur pour replacer les signaux reçus en bande de base et délivrer une composante en phase sur une voie en phase et une composante en quadrature sur une voie en quadrature,
• un dispositif électronique selon un aspect de l'invention pour estimer des symboles à partir des composantes en phase et en quadrature.

The present invention also relates to a device for receiving terrestrial broadcast signals comprising:

• a tuner for repositioning the received baseband signals and delivering an in-phase component on an in-phase channel and a quadrature component on a quadrature channel,
• an electronic device according to one aspect of the invention for estimating symbols from the in-phase and quadrature components.

Such a device for receiving broadcast signals can be relatively compact.

Other features and advantages of the present invention will become apparent from the description hereinafter.

Fig. 1 is a diagram of an exemplary radio broadcast signal receiving apparatus according to an embodiment of the present invention.

Figure 2 shows an exemplary phase correction method according to an embodiment of the present invention.

Figure 3A shows an example constellation of estimated symbols without phase correction.

Fig. 3B shows an example of an estimated symbol constellation with phase correction according to an embodiment of the present invention of 0.5 degrees.

Fig. 3C shows an example of an estimated symbol constellation with phase correction according to an embodiment of the present invention of 2 degrees.

Fig. 3D shows an example of an estimated symbol constellation with phase correction according to an embodiment of the present invention of 2.5 degrees.

Figure 4 shows an exemplary amplitude correction method, according to an embodiment of the present invention.

Device for receiving broadcast signals

The receiving device 1 of FIG. 1 comprises a tuner 2 and an electronic device 3. The reception device 1 can be produced in mixed technology.

The tuner 2 is capable of receiving terrestrial broadcast signals and resetting these signals to the baseband. In this example, the broadcast signals are modulated by a COFDM modulation. The electronic device 3 can process components in phase S _I and S _Q quadradure from relocated baseband signals.

The electronic device shown comprises two digital analog converters (4, 5) for digitizing the components in S _I phase and quadradure S _Q , thereby creating a digital signal S _DI phase and a quadrature digital signal S _DQ .

The electronic device shown 3 also comprises a symbol estimation device from the digital signal in S _DI phase and the digital quadrature signal S _DQ . The symbol estimation device comprises a digital processing device 6 and digital low pass filters (8, 9). These digital low-pass filters (8, 9) make it possible to provide relatively selective filtering.

The digital processing device 6 demodulates a corrected phase signal S ' _DI and a corrected quadrature signal S' _DQ . The corrected phase signal S ' _DI and the corrected quadrature signal S' _DQ come respectively from the digital signal in phase S _DI and the digital signal in quadrature S _DQ .

The digital processing device 6 may include a rotation device (not shown) for placing the baseband signals with relatively high accuracy. The digital processing device 6 may also include a low pass filter (not shown) and a fast Fourier transform device (not shown). A memory (not shown) can indicate the modulation mode, for example QPSK (as "Quaternary Phase Shift Keying" in English), 16-QAM (as "Quadrature Amplitude Modulation" in English) or 64-QAM.

The digital processing device 6 is in itself well known to those skilled in the art. The digital processing device 6 makes it possible to obtain a constellation of symbols.

The electronic device 3 may also comprise an automatic gain control circuit (not shown) acting on the gain of amplifiers (not shown) upstream of the digital analog converters (4, 5). The automatic gain control circuit makes it possible to place the amplitudes of the components in phase and in quadrature in a range of values such that the conversion is optimal.

The electronic device shown 3 also comprises channel estimation means, for example a predictor 7. The predictor 7 makes it possible at least partially to compensate for the effects of the channel on the symbols obtained.

The electronic device shown 3 also comprises a device for correcting mismatches between the digital signal in the S _DI phase and the quadrature digital signal S _DQ . The pairing error correction device comprises an amplitude correction device 10 and a phase correction device 11.

Device and method of amplitude correction

The amplitude correction device 10 of FIG. 1 and the exemplary amplitude correction method of FIG. 4 will be commented simultaneously.

The amplitude correction device 10 comprises, in this embodiment, two power calculation devices (12, 13), each power calculation device making it possible to evaluate a power P (I) or P (Q). on one of the channels I or Q. Each power can be instantaneous, or averaged over a given time. For each channel, a power is evaluated (step (j) in FIG. 4).

In the example of FIG. 2, the power calculation devices (12, 13) use an intermediate phase signal S _DII or an intermediate quadrature signal S _DQI according to the channel to which they are connected in order to estimate the power of this signal. way. The intermediate phase signal S _DII and the intermediate quadrature signal S _DQI come from the digital signal in the S _DI phase and the quadrature digital signal S _DQ .

The amplitude correction device 10 further comprises second comparison means 14 for comparing the powers thus evaluated. This step, referenced (k) in FIG. 4, for comparing the powers evaluated in step (j) can be implemented in multiple ways.

For example, a gain step g can be used to perform this comparison. The gain step g can be programmed. One of the evaluated powers, for example the power P (I) on the channel I, is first multiplied by a first factor, for example (1 + g), before being compared with the other power, for example the power P (Q) on the channel Q. The power P (I) on the channel I is also multiplied by a second factor, for example (1-g), before being compared with the power P (Q ) on the channel Q. A first difference D1, equal to | P (I) (1 + g) - P (Q) | and a second difference D2, equal to | P (I) (1-g) - P (Q) | can for example be evaluated (step 50 in FIG. 4). The first difference D1 is compared with the second difference D2 (step 51).

According to an alternative embodiment and not shown, the power comparison does not involve a gain step. For example, the powers P (I) and P (Q) can be compared directly with each other.

Returning to FIG. 1, a result of the comparison, for example the value of a Boolean variable, is transmitted to gain distribution means 15 connected to the second comparison means 14.

The gain distribution means 15 make it possible to choose a gain correction value δ _G from at least two gain correction values (step (I) in FIG. 4).

Advantageously and in a nonlimiting manner, the value of the gain correction δ _G is chosen from strictly two values. Advantageously and in a nonlimiting manner, the strictly two potential gain correction values have opposite signs. Advantageously, these two values are substantially equal in absolute value, for example the values (-g / 2, + g / 2).

If the first difference D1 is smaller than the second difference D2, it can be considered that the power in the channel I is too low and the value of the selected gain correction δ _G is then + g / 2 (step 53 in the figure 4).

If the first difference D1 is higher than the second difference D2, we can consider that the power in the channel I is too much and the value of the selected gain correction δ _G is then -g / 2 (step 52 in FIG. 4).

The amplitude correction device 10 of FIG. 2 further comprises two multipliers (16, 17). Each multiplier (16, 17) is located on one of the upstream channels of the corresponding power calculation device (12, 13). Each multiplier makes it possible to apply a gain corresponding to the channel on which it is located.

For each of the channels, the current gain to be applied to this channel can be determined from a previous gain applied to this channel on the one hand, and from the value of the selected gain correction δ _G (step (m) on the Figure 4). The gain of a multiplier 17 of the in-phase channel is for example multiplied by a factor of approximately (1+ δ _G ). The gain of a multiplier 16 of the quadrature channel is for example multiplied by a factor of approximately (1- δ _G ). The gain of each multiplier is determined by the gain distribution means 15.

According to an alternative embodiment and not shown, the current gain to be applied to a channel is determined only for one of the channels. The current gain is determined from an earlier gain applied to this channel on the one hand, and the gain correction value on the other hand. For example, only the gain of the multiplier 17 of the in-phase channel is multiplied by a factor (1 + 2 * δ _G ).

The power calculating devices (12, 13), the second comparing means 14, and the gain distributing means can operate continuously. Steps (j), (k), (l), (m) and the step of applying the current gain are thus repeated. The amplitude matching defects are thus corrected step by step.

In this example, the potential values of the gain correction (-g / 2; + g / 2) derive from the value of the gain step g, but it may be otherwise arranged.

The absolute value of the gain correction may for example correspond to a gain of 0.17dB.

It can also be expected that several absolute values of gain corrections are possible, for example g / 2 and 2g. Thus, several modes can be envisaged: for example a slow mode in which one converges relatively slowly towards a correction of the defects of pairing in amplitude and a fast mode in which convergence is faster. In slow mode, the gain of the multiplier 17 of the in-phase channel can only be multiplied by a factor (1 + g / 2) or (1-g / 2). In fast mode, the gain of the multiplier 17 of the in-phase channel can only be multiplied by a factor (1 + 2g) or (1-2g). The slow mode can for example be adopted when the electronic device 3 operates in steady state. The fast mode can for example be adopted when the electronic device 3 is in transient state.

Other amplitude correction devices than that shown may be used.

Phase correction device

The pairing error correction device may also comprise a phase correction device 11.

The phase correction device 11 comprises a measuring device 23 of the first error values ∈ _i located downstream from the predictor 7. The first errors ∈ _i are measured between a symbol estimated by the digital processing device 6 and the predictor 7 , and a theoretical symbol closest to the estimated symbol. The first error may include the distance between the point corresponding to the estimated symbol and the point corresponding to the theoretical symbol on a constellation.

Summing means 18 make it possible to determine the current value of a second error from a sum of the values of the first measured errors ∈ _i during a first duration T ₁ . The current value of the second error may for example be a sum, possibly weighted, of the first measured errors ∈ _i , or even an average.

Furthermore, the phase correction device 11 comprises storage means (not shown), for example a memory, for retain the previous value value of the second error and an earlier phase shift correction.

First comparison means, here confused with summing means 18, make it possible to compare the current value of the second error with the previous value of the second error. Means of choice, here confused with the summing means 18, make it possible to choose the value of a current phase shift correction among two phase shift correction values. The choice is made from a result of the comparison on the one hand, and the value of the previous phase shift correction stored in memory on the other hand.

The summing means 18, the first comparison means and the means of choice can be integrated in a single processor.

Phase shifting means (19, 20) are used to introduce a current phase shift between the in-phase digital signal and the quadrature digital signal. The current phase shift is a function of the value of the current phase shift correction and an earlier phase shift. The current phase shift is chosen equal to the previous phase shift plus the phase shift correction chosen. The phase shift increases or decreases according to the sign of the chosen phase shift correction.

The phase-shifting means may comprise a phase recovery circuit 20 and a table 19. The table 19 makes it possible to provide a first value A and a second value B from the desired phase shift. This first value A and this second value B are injected into the phase recovery circuit 20. For a phase shift value of φ, the first value may be substantially equal to cos (φ / 2) / (2 * cos (φ) ) and the second value may be substantially equal to sin (φ / 2) / (2 * cos (φ)). In practice, it can be provided that the phase shift remains within a certain range, for example [-8 °; + 8 °]. As the phase shift is likely to vary in a discrete manner, with phase shift corrections, for example of -1 ° ° or + 1 ° only, the table 19 comprises a table of relatively reasonable size.

Phase shift corrections may also have higher or lower absolute values, for example 0.1 degrees.

This phase correction device makes it possible to converge towards an adequate phase shift value.

The summing means 18 are here controlled by first counting means 21 and by second counting means 22.

The first counting means only allow the summation of the first measured errors ∈ _i during the first duration T ₁ . This summation over a plurality of first error values makes it possible to at least partially absorb variations of the channel over time.

The second counting means 22 authorize the summation only after having passed a certain period of time corresponding to a second duration T ₂ . This period of time may allow the electronic device 3 to regain a steady state after the modification of the phase shift provided. A new value of the second error is therefore established only after this second duration T ₂ .

The first duration may for example be 1 ms, or 8 s. The second duration can also have various values, for example 10 ms.

In this example, the phase correction is performed before the amplitude correction. It can of course be otherwise.

Method for correcting phase matching defects

FIG. 2 shows an example of a pairing error correction algorithm according to an embodiment of the invention.

This method comprises a step (b) of determining the current value of a second error E. The current value of this second error E is compared with the previous value of the second error E _prev (step (c)). The value of a current phase shift correction δ is chosen (step (d)) from among two phase shift correction values (-δ _p , + δ _p ) according to the result of the comparison and the value of an earlier phase shift correction δ _p . The value of the current phase shift correction δ chosen is added to an earlier phase shift φ (step (e)), to obtain the value of a current phase shift. This current phase shift is introduced between a digital signal in phase and a digital signal in quadrature, for example with a table and a phase recovery circuit.

These steps are intended to be repeated regularly. The algorithm can provide an expectation (step (g)) for a second duration T ₂ between two execution cycles, this second duration T ₂ possibly being zero or modified.

During a first cycle, the algorithm can provide initiation steps (39, 38).

The value of the earlier phase correction δ _p is thus initialized (step 39) to a certain value Δφ ₀ . In the example shown, this certain value Δφ ₀ corresponds to the desired phase shift step. The higher Δφ ₀ is, the faster the convergence.

In the same way, the previous value of the second error E _prev is initialized (step 38), for example to zero. Alternatively, this first previous value of the second error is measured before the execution of the first cycle.

The first cycle comprises a step (a) of measuring a set of first error values ∈ _i during a first duration T ₁ .

In this example, the measurements (step 35) take place only during the first duration T ₁ . Step (a) comprises for this purpose a loop on an index i, with initiation steps of loop 40, test 41 and incrementation 42.

Alternatively, first errors are measured continuously and the set of first error values ∈ _i includes only the first error values ∈ _i measured during the first duration T ₁ , as in the device of FIG.

The first error values ∈ _i of the set of first error values are summed (step (b)) to determine the current value of the second error E. In this example, we sum the absolute values of the first errors ∈ _i .

This current value of the second error E is compared with the previous value of the second error E _prev (step (c)). During the first cycle, with an earlier value of the second error E _prev null, the algorithm shown leads to choose (step 33) the opposite of the value of the previous phase shift correction δ _p as current phase correction value δ , ie -Δφ ₀ . The phase shift pitch Δφ ₀ is therefore subtracted from the current phase shift φ (step (e)).

Before the execution of step (e), the current phase shift φ may have an arbitrarily chosen value. This value can be null.

After the execution of step (e), the phase shift is introduced between the I and Q channels.

The current value of the second error E is retained as the previous value of the second error E _prev and the value of the current phase shift correction δ is retained as an earlier phase shift correction δ _p (step (f)).

After the execution of the step (g) of waiting during the second duration T ₂ , a new cycle can start again.

"Current" refers to the current cycle, while "previous" refers to a previous cycle, or an initialization.

During this new cycle, the previous value of the second error E _prev is compared with the current value of the second error E, measured during the new cycle.

If the current value of the second error E is greater than the previous value of the second error E _prev , measured during the first cycle, it is considered that the phase shift correction introduced has not helped compensate for the actual phase difference between the signals. On the contrary, it is estimated that the phase shift correction introduced has aggravated the real phase difference between the signals of the I and Q channels. Consequently, the value of the current phase shift correction δ is chosen to be equal to the opposite of the prior phase shift correction δ _p (step 33).

Alternatively, it can be provided that in step 33, the value of the current phase shift correction δ is chosen equal to twice the opposite of the previous phase shift correction δ _p . This avoids losing a cycle to return to a status quo.

If the current value of the second error E is smaller than the previous value of the second error E _prev , measured during the first cycle, it is estimated that the phase shift introduced has helped to compensate for the actual phase difference between the signals of the channels I and Q. Accordingly, the value of the current phase shift correction δ is chosen equal to the previous phase shift correction δ _p (step 34).

By repeating these cycles periodically, one converges to a phase shift value close to the actual phase shift between the I and Q channels.

Example of phase correction

Figure 3A shows an example constellation of estimated symbols without phase correction. The actual phase shift between I and Q channels is 2.2 degrees. A set of spots can be observed: the estimated symbols are only close to the theoretical symbols.

When a phase correction algorithm such as that of FIG. 2 is applied to such signals, this state of affairs can be improved, as shown by the constellations of FIGS. 3B, 3C and 3D.

We choose a zero initial phase shift, and a phase shift step of 0.5 degrees. After performing a first cycle, a +0.5 degree phase shift was introduced between I and Q channels. As shown in the constellation in Figure 3B, the spots are smaller than the spots in Figure 3A. .

Also, when executing a second cycle, it is judged that the phase shift of +0.5 degrees improves the correction of the mismatches between channels I and Q. A new correction of phase shift of 0.5 degrees is introduced, a phase shift of 1 degree.

Other cycles are executed and the phase shift introduced is close to the actual phase shift. As shown in Figures 3C and 3D, the spots are substantially similar for an introduced phase shift of 2 degrees (Figure 3C) and an introduced phase shift of 2.5 degrees (Figure 3D).

When these values are reached, the estimated symbols are relatively close to the theoretical symbols.

variants

With an algorithm such as that of FIG. 2, the introduced phase shift will oscillate around the actual phase shift.

It can be expected to increase the value of the second duration when a number of cycles have been executed. Indeed, it can be estimated that after a certain number of cycles, the value of the introduced phase shift is relatively close to the value of the actual phase shift. Cycles can therefore be run more episodically for monitoring purposes.

It is also possible to provide a relatively high value of the phase shift Δφ ₀ during the execution of the first cycles and then lower. Indeed, the actual phase shift can be relatively different from the arbitrarily chosen phase shift value, so that a relatively high phase shift step converges more quickly towards the value of the actual phase shift.

Claims (13)

A method of correcting pairing faults between a digital in-phase signal and a quadrature digital signal, respectively on a in-phase and a quadrature channel, from a terrestrial broadcast signal, comprising a method of correcting phase comprising the steps of / a / measuring a set of first error values during a first duration, each of which is measured from an estimated symbol from the broadcast signal and the theoretical symbol closest to the estimated symbol, / b / determining a current value of a second error from a sum of the first error values of the first error value set, / c / comparing the current value of the second error with an earlier value of the second error stored in memory, / d / selecting the value of a current phase shift correction to be added to an earlier phase shift introduced between the in-phase digital signal and the quadrature digital signal, the choice being made among at least two phase shift correction values, starting from result of the comparison of step / c / on the one hand, and the value of an earlier phase shift correction stored in memory on the other hand, / e / adding the value of the current phase shift correction chosen in step / d / to the previous phase shift to obtain a current phase shift, / f / introducing the current phase shift obtained in step / e / between the in-phase digital signal and the quadrature digital signal, / g / keeping in memory the current value of the second error determined in step / b / and the value of the current phase shift correction chosen in step / d /, / h / repeat the previous steps. The process of claim 1 wherein
during step / d /, the choice of the current phase shift correction value is made from strictly two phase shift correction values, of opposite signs from each other. The method according to one of the preceding claims, wherein the phase correction method further comprises the step of
/ i / wait for a second time. Method according to one of the preceding claims, wherein
the first duration is such that the set of first error values comprises at least four first error values. The method of one of the preceding claims, further comprising an amplitude correction method, comprising the steps of
/ j / evaluate a power for each channel,
/ k / compare the powers evaluated in step / j /,
/ I / selecting a gain correction value from at least two gain correction values, from a result of the comparison,
/ m / for at least one of the channels, determine the current gain to be applied to this channel, from a previous gain applied to this channel on the one hand, and the gain correction value chosen on the other hand,
/ n / for each channel for which a current gain has been determined in step / m /, apply this current gain to this channel, and
/ o / repeat the steps / j /, / k /, / l /, / m / and / n /. Device for correcting pairing faults between a digital in-phase signal (S _DI ) and a quadrature digital signal (S _DQ ), respectively on a in-phase channel and a quadrature channel, originating from a broadcast signal by way of Earth and intended for a symbol estimation device from the in-phase digital signal (S _DI ) and the quadrature digital signal (S _DQ ), the correction device comprising a phase correction device (11),
characterized in that the phase correction device comprises
means for storing the value of an earlier phase shift correction (δ _p ) and the previous value of a second error (E _prev ),
a first error value measuring device (23) (∈ _i ) between an estimated symbol and a theoretical symbol closest to the estimated symbol,
summing means (18) for determining the current value of a second error (E) from a sum of the first error values measured during a first duration ( T ₁ ),
first comparing means (18) for comparing the current value of the second error with the previous value of the second error stored in memory,
means for selecting (18) the value of a current phase shift correction (δ) to be added to an earlier phase shift (φ) introduced between the in-phase digital signal and the quadrature digital signal, the choice being made among at least two phase shift correction values, from the result of the comparison on the one hand, and the value of the previous phase shift correction stored in memory,
phase shifting means (19, 20) for introducing a current phase difference between the in-phase digital signal and the quadrature digital signal, the current phase shift being a function of the previous phase shift and the value of the current phase shift correction. A mismatch correction device according to claim 6, wherein the phase correction device further comprises
first counting means (21) controlling the summing means (18) to allow summation of the first error values (∈ _i ) during the first duration ( T ₁ ). A pairing error correction device according to one of claims 6 to 7, wherein the phase correction device further comprises
second counting means (22) controlling the summing means (18) to allow summation of the first error values (∈ _i ) only after a second duration ( T ₂ ). A pairing error correction device according to one of claims 6 to 8, further comprising
channel estimation means (7) located upstream of the first error value measuring device (23) (∈ _i ). A mismatch correction device according to one of claims 6 to 9, further comprising an amplitude correction device (10) comprising
two power calculation devices (12, 13), each power calculation device for evaluating a power on one of the channels,
second comparing means (14) for comparing the powers evaluated by the power calculating devices,
gain distribution means (15) connected to the second comparing means, for selecting a gain correction value from at least two gain correction values, and
two multipliers (16, 17), each multiplier being situated on one of the channels upstream of the corresponding power calculation device, the gain of each multiplier being determined by the distribution means of the multipliers gains from an earlier gain corresponding to this multiplier and the selected gain correction value. An electronic component (3) for processing in-phase (S _I ) and quadrature (S _Q ) components, respectively on a in-phase and a quadrature path, from terrestrial broadcast signals, comprising
a symbol estimator from a digital in-phase signal (S _DI ) and a quadrature digital signal (S _DQ ) corresponding respectively to the in-phase component and the quadrature component, and
a pairing error correction device according to one of claims 6 to 10. Device for receiving (1) broadcast signals by terrestrial means comprising
a tuner (2) for repositioning the received baseband signals and delivering an in-phase component (S _I ) on an in-phase channel and a quadrature component (S _Q ) on a quadrature channel,
an electronic device (3) according to claim 11 for estimating symbols from the in-phase and quadrature components. Broadcast signal receiving device (1) according to claim 12, characterized in that the receiving device is made of mixed technology.

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